Recovery of data and data processes

ABSTRACT

One embodiment of a data recovery management system includes prompt logic operable to prompt a user to provide information describing impact that an extended interruption of a project tracking system would have on an work unit that uses the project tracking system to perform a particular workflow process; a database coupled to the prompt logic, operable to store feedback received from the user in response to answering questions proposed by the prompt logic; and organizational logic operable to compile information stored in the database for each work unit that utilizes the project tracking system to perform a particular workflow process. Other systems and methods are also provided.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to copending U.S. provisional application entitled, “TRAKS SYSTEM,” having Ser. No. 60/811,677, filed Jun. 7, 2006, which is entirely incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates generally to computer systems and processes, and more particularly to recovery of computer systems and processes.

DESCRIPTION OF THE RELATED ART

In order to stay current with demand, telecommunications networks have grown at an exponential rate. This is especially true for common local exchange carriers (CLECs/common carriers), which are required by federal law to service any demand, even when costs would normally be prohibitive. Moreover, these common carriers must maintain capacity and plan for this ever-increasing demand, and supply leased-line bandwidth to competitors. Thus, the telecommunications network is ever evolving to meet the needs and demands of consumers.

Carriers have developed various procedures over the years to respond to their customers. In particular, a network operations center (NOC) includes engineers who typically generate engineering work-orders (EWOs). The EWOs are typically sent to a record maintenance center (RMC) group, typically consisting of a number of draftsmen, and a construction group. The RMC group is typically where the engineering work order is pre-posted. Pre-posting typically includes altering the existing drawing records. Outside plant construction management then typically builds the changes into the network. Upon making the changes, outside plant construction management typically closes the job in job management system (JMS). The designing engineer can then approve the drawings and send the changes back to the RMC, and the RMC can final-post drawings. Final posting typically involves checking the construction against the work order and resolving any differences. These changes can involve 15,000 jobs per month, in one example, among others. This volume can result in significant backlogs of up to many years for some RMCs.

New revisions to software and equipment are an ongoing challenge as new projects are brought online. Implementing a way to continue business in a coherent way during a possible disaster event is an imperative.

Therefore, there is a need for systems and methods that address these and/or other perceived shortcomings of the prior art.

SUMMARY OF THE DISCLOSURE

Embodiments of the present disclosure provide a data recovery management system and method for managing recovery of data and data processes. Briefly described, one embodiment of the system, among others, includes prompt logic operable to prompt a user to provide information describing impact that an extended interruption of a project tracking system would have on an work unit that uses the project tracking system to perform a particular workflow process; a database coupled to the prompt logic, operable to store feedback received from the user in response to answering questions proposed by the prompt logic; and organizational logic operable to compile information stored in the database for each work unit that utilizes the project tracking system to perform a particular workflow process.

Embodiments of the present disclosure can also be viewed as providing methods for managing recovery of data and data processes. In this regard, one embodiment of such a method, among others, can be broadly summarized by the following steps: prompting a user to provide information describing impact that an extended interruption of a project tracking system would have on an work unit that uses the project tracking system to perform a particular workflow process; storing feedback received from the user; and compiling information stored in a database for each work unit that utilizes the project tracking system to perform a particular workflow process.

Other systems, methods, and/or devices according to embodiments will be or become apparent to one with skill in the art upon review of the following drawings and detailed description. It is intended that all such additional system, methods, and/or computer program products be included within this description, and be within the scope of the present disclosure.

BRIEF DESCRIPTION OF THE FIGURES

The disclosure can be better understood with reference to the following drawings. The components in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the present disclosure. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views.

FIG. 1A is a block diagram of an embodiment, among others, of a tracking and assignment system and disaster recovery system of the present disclosure.

FIG. 1B is a generic block diagram of an embodiment, among others, of a tracking and assignment system server of FIG. 1.

FIG. 2A is a sample screen shot of an embodiment, among others, of a main menu screen representation of the TRAKS application of FIG. 1B.

FIG. 2B is a sample screen shot of an embodiment, among others, of a drawing conversion menu screen representation of the TRAKS application of FIG. 1B.

FIG. 2C is a sample screen shot of an embodiment, among others, of a fiber splice menu screen representation of the TRAKS application of FIG. 1B.

FIG. 3 is a sample screen shot of an embodiment, among others, of a split plat (SPLAT) request screen representation of the TRAKS application of FIG. 1B.

FIG. 4 is a sample screen shot of an embodiment, among others, of an opening split plat assignment page screen representation of the TRAKS application of FIG. 1B.

FIG. 5 is a sample screen shot of an embodiment, among others, of a split plat assignment page screen representation of the TRAKS application of FIG. 1B.

FIG. 6 is a sample screen shot of an embodiment, among others, of a split plat file front page screen representation of the TRAKS application of FIG. 1B.

FIG. 7 is a sample screen shot of an embodiment, among others, of a split plat state selection reporting page screen representation of the TRAKS application of FIG. 1B.

FIG. 8 is a sample screen shot of an embodiment, among others, of a split plat open jobs reporting screen representation of the TRAKS application of FIG. 1B.

FIG. 9 is a sample screen shot of an embodiment, among others, of a split plat open jobs by ID reporting screen representation of the TRAKS application of FIG. 1B.

FIG. 10 is a sample screen shot of an embodiment, among others, of a split plat open jobs reporting by ID screen representation of the TRAKS application of FIG. 1B.

FIG. 11 is a sample screen shot of an embodiment, among others, of a fiber conversion start printing screen representation of the TRAKS application of FIG. 1B.

FIG. 12 is a sample screen shot of an embodiment, among others, of a fiber conversion wirecenter printing report screen representation of the TRAKS application of FIG. 1B.

FIG. 13 is a sample screen shot of an embodiment, among others, of a fiber conversion wirecenter availability report screen representation of the TRAKS application of FIG. 1B.

FIG. 14 is a sample screen shot of an embodiment, among others, of a fiber conversion wirecenter assignment screen representation of the TRAKS application of FIG. 1B.

FIG. 15 is a sample screen shot of an embodiment, among others, of a fiber conversion wirecenter completion screen representation of the TRAKS application of FIG. 1B.

FIG. 16 is a sample screen shot of an embodiment, among others, of a split plat (SPLAT) request screen representation of the TRAKS application of FIG. 1B.

FIG. 17 is a sample screen shot of an embodiment, among others, of a fiber conversion wirecenter availability report screen representation of the TRAKS application of FIG. 1B.

FIG. 18 is a sample screen shot of an embodiment, among others, of a fiber conversion completed wirecenters report screen representation of the TRAKS application of FIG. 1B.

FIG. 19 is a sample screen shot of an embodiment, among others, of a fiber conversion accepted wirecenters report screen representation of the TRAKS application of FIG. 1B.

FIG. 20 is a sample screen shot of an embodiment, among others, of a fiber conversion summary screen representation of the TRAKS application of FIG. 1B.

FIG. 21 is a sample screen shot of an embodiment, among others, of a fiber splice unassigned jobs screen representation of the TRAKS application of FIG. 1B.

FIG. 22 is a sample screen shot of an embodiment, among others, of a fiber splice assignment screen representation of the TRAKS application of FIG. 1B.

FIG. 23 is a sample screen shot of an embodiment, among others, of a fiber splice completion opening screen representation of the TRAKS application of FIG. 1B.

FIG. 24 is a sample screen shot of an embodiment, among others, of a fiber splice completion screen representation of the TRAKS application of FIG. 1B.

FIG. 25 is a sample screen shot of an embodiment, among others, of a fiber splice assignment by ID screen representation of the TRAKS application of FIG. 1B.

FIG. 26 is a sample screen shot of an embodiment, among others, of a fiber splice reporting by ID screen representation of the TRAKS application of FIG. 1B.

FIG. 27 is a sample screen shot of an embodiment, among others, of a fiber splice completed jobs reporting by ID opening screen representation of the TRAKS application of FIG. 1B.

FIG. 28 is a sample screen shot of an embodiment, among others, of a fiber splice completed jobs reporting screen representation of the TRAKS application of FIG. 1B.

FIG. 29 is a sample screen shot of an embodiment, among others, of a fiber splice reporting by records maintenance center screen representation of the TRAKS application of FIG. 1B.

FIG. 30 is a sample screen shot of an embodiment, among others, of a fiber splice completed jobs reporting screen representation of the TRAKS application of FIG. 1B.

FIG. 31 is a sample screen shot of an embodiment, among others, of a fiber splice records maintenance center reporting screen representation of the TRAKS application of FIG. 1B.

FIG. 32 is a flowchart illustrating the operation of an embodiment, among others, of the split plat management system of the TRAKS application of FIG. 1B.

FIG. 33A is a flowchart illustrating the operation of an embodiment, among others, of the drawing conversion management system of the TRAKS application of FIG. 1B.

FIG. 33B is a continuation of the flowchart of FIG. 33A illustrating the operation of an embodiment, among others, of the drawing conversion management system of the TRAKS application of FIG. 1B.

FIG. 34 is a flowchart illustrating the operation of an embodiment, among others, of the fiber splice management system of the TRAKS application of FIG. 1B.

FIGS. 35-40 are diagrams of a Web-based interface to a disaster recovery system of FIG. 1.

FIGS. 41-42 are diagrams of a Web-based interface to a disaster recovery system of FIG. 1.

FIG. 43 is a diagram of compiled information from data obtained using the interface forms of FIGS. 35 and 41.

FIG. 44 is a flow chart diagram of one embodiment of a method for providing a disaster recovery plan to the TRAKS system of FIG. 1.

FIG. 45 is a flow chart diagram of one embodiment of a process for constructing a disaster recovery procedure for a business unit using the disaster recovery system of FIG. 1.

FIG. 46 is a flow chart diagram of one embodiment of a process for reporting a disaster situation with respect to TRAKS of FIG. 1.

FIG. 47 is a flow chart diagram of one embodiment of a method for managing a recovery of data and data processes in accordance with FIG. 1.

DETAILED DESCRIPTION

Embodiments of the disclosure now will be described more fully with reference to the accompanying drawings. The disclosure may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are intended to convey the scope of the disclosure to those skilled in the art. Furthermore, all “examples” given herein are intended to be non-limiting.

Referring now to FIG. 1, shown is a block diagram of a typical network 100 in which an embodiment, among others, of the present disclosure can be employed. Network planning 105 typically includes a group of engineers in charge of changes to a telecommunications network infrastructure. An example, among others, of an item causing such changes is a new service request, such as when a new subdivision or new home is being built. The changes can also be upgrades to the network to deal with existing traffic, future plans, reconfiguration of the infrastructure, etc. One skilled in the art should recognize that there exist myriad reasons why telecommunications network infrastructure changes.

When planning a change to the telecommunications network infrastructure, engineers at the network planning 105 typically request a drawing from drawings archives 130 using a program such as Map Viewer, available from Byers Engineering, of Atlanta, Ga. Using the Map Viewer program, the engineer pulls a drawing by copying it onto a local computer (not shown) and can typically redline with changes the plat drawing pulled using a CAD program, but this does not make changes to the official record of the plat. Upon making the changes and calculating costs, the engineer will typically launch the change request to a supervisor through a job management system (JMS) 110, such as one available from CEYONIQ, Inc., of Herndon, Va. (world headquarters in Bielefeld, Germany), as one example among others. The supervisor typically reviews the changes and either approves the changes or denies the request using JMS 110. Typically, if the supervisor denies the request, he or she will suggest an alternative to the requesting engineer, and the engineer submits an altered request.

Upon approval by the supervisor, the work order is typically automatically launched by JMS 110 to a records maintenance center (RMC) workbasket. The RMC workbasket is a database directory associated with the RMC group that typically resides on a centralized workbasket server 115, which may be co-located with the JMS server 110 (though drawn separately for clarity). A pre-posting receipt worker in the RMC group typically retrieve jobs from the workbasket server 115 at various intervals using a workstation (not shown). The pre-posting receipt worker receipts these jobs by printing the jobs and entering them into a tracking reporting and knowledgebase system (TRAKS) server(s) 120 of the present disclosure.

In one embodiment, TRAKS 120 is a Web based, database driven, suite of applications that are used to facilitate the tracking and expedition of Outside Plant Maintenance Records across multiple states served by a service provider, such as a telecommunications provider, among others. TRAKS, in one embodiment, utilizes a wide-ranging suite of Operating Systems and backbone software packages including Solaris UNIX, Windows, Oracle, MySQL, Apache, and PHP for maximum flexibility and reliability when scaling software solutions. A disaster recovery system (DRS) 122 is provided to ensure operability of TRAKS operations in case of a disaster event, as discussed hereinafter.

The TRAKS servers 120 in some implementations, among others, of the present disclosure, can include interfaces to barcode scanners, printers, label software, as well as legacy software applications.

TRAKS 120 typically already has a record of jobs that are expected to be in the workbasket 115 because it retrieves newly approved job numbers from a job number assignment application, one example, among others, of such an application is an IDEAL application 125, which is available from BellSouth of Atlanta, Ga. IDEAL 125 is a legacy system that assigns job numbers to JMS 110 when an engineer at network support 105 gets approval for a new project. Thus, TRAKS 120 can determine any irregularities between the job numbers that have been approved and the copies actually received via the JMS workbasket 115. If a job has been approved and not receipted into TRAKS 120, a manager can be made aware of this fact through TRAKS 120, whereas it was previously impractical to determine whether a copy of a job was supposed to be received.

The process of receipting a job into TRAKS 120 typically includes reviewing the job and determining the difficulty level of the job, and the number of pages that require posting. Because posting staff employees in an embodiment, among others, of TRAKS work on contract (e.g. are paid by a separate entity according to a per piece, or credit system), the difficulty level and number of pages requiring posting determine the credit that a poster (posting staff employee) will receive for posting a particular job. Typically TRAKS allows the user to select the job number and enter the difficulty and the post-able pages. The employee receipting the job typically also prints a barcode label representing the job number of the job using TRAKS, and a front sheet containing the pertinent information about the job (i.e. NPA, NNX, district, wirecenter etc.).

After receipting a job, the employee doing the receipting typically takes the hard copies, labels, and front sheets to a file clerk. The file clerk assembles the file and puts it into a file room. Assembling the file typically involves attaching the label to a file folder, and inserting the front sheet and hard copy into the file folder. The file clerk then places the file into the file room for later retrieval by a pre-posting employee (pre-poster) or team leader.

Typically a team-leader for a pre-posting group will retrieve a number of pre-post jobs from the file room by assigning a number of files to members of his or her group using the members' respective identification codes. The team-leader typically assigns the files, one file per job, to his or her team members (pre-posters) by scanning the file using a barcode scanner, and entering an identification code for a group member into TRAKS. Typically, TRAKS also retrieves data from IDEAL that indicates that a job has been canceled by network planning 105, such that a user is made aware of the fact that a job has been canceled before pre-posting the job associated with that job number. Jobs can be canceled for numerous reasons, including cancellation by the customer, not enough funds, cutbacks, etc.

Then a pre-poster receives the files that were assigned to his or her identification code. After being assigned a job, the pre-poster has a period of time to complete the job. The pre-poster will then typically enter the drawing changes into a computer assisted drawing (CAD) program, such as Engineering Work Order (EWO) system (not shown). EWO is an intelligent, Oracle-based database program available from Byers Engineering, of Atlanta, Ga., and one skilled in the art should recognize that Oracle is available from Oracle Corporation of Redwood Shores, Calif. The EWO system provides data to the pre-poster's computer from the drawings archives 130, and allows the pre-poster to change the EWO drawings. Upon completing the job, the pre-poster turns the job into his or her supervisor. The supervisor then scans the barcode and selects a TRAKS option to close the pre-post job.

Outside plant construction then picks up the job from the RMC. Outside plant construction typically includes a Outside Plant Construction Management (OSPCM) system that aids the outside plant construction employees. After completing construction on a job, construction uses OSPCM to close a job, and the RMC uploads the OSPCM closing information into a TRAKS final post receipt table. The RMC then waits for someone from network planning to review the construction and reconcile any changes in an as-built drawing (as provided by the construction group) in a CAD program.

After network planning has reviewed a completed job the network planning engineer manually launches the as-built drawing(s) to the RMC's JMS workbasket 115, and the RMC receives approval (in the form of the OSPCM closing information, which was previously discussed) from network planning to perform a final posting on the job. The receipt process is similar to the process for receiving a pre-post job with drawings. However, the final posting typically includes a reconciliation by a draftsman (poster) of the changes shown in the original engineering drawings that were pre-posted against the changes shown in the as-built drawing. Any differences are added into the final post drawings and the file is then sent to the drawings archive 130. In particular, paper copies are typically sent to an archiving facility associated with a regional bell operating company (RBOC), while electronic copies are sent, for example, among others, to a JMS Docutrieve archives Docutrieve is available from CEYONIQ, Inc., of Herndon, Va. (world headquarters in Bielefeld, Germany), and is a software product intended to be used with JMS. One skilled in the art should recognize that the disclosure is not intended to be limited to RBOCs, but could include other entities that build and maintain drawings or blueprints.

Referring now to FIG. 1B, shown is a block diagram of an embodiment, among others, of the TRAKS server 120 shown in FIG. 1A. Generally, in terms of hardware architecture, as shown in FIG. 1B, the TRAKS server 120 includes a processor 135, memory 140, and one or more input and/or output (I/O) devices 145 (or peripherals) that are communicatively coupled via a local interface 150. The local interface 150 is, for example, among others, one or more buses or other wired or wireless connections, as is known in the art. The local interface 150 may have additional elements, which are omitted for simplicity, such as controllers, buffers (caches), drivers, repeaters, and receivers, to enable communications. Further, the local interface may include address, control, and/or data connections to enable appropriate communications among the aforementioned components.

The processor 135 is a hardware device for executing software, particularly that stored in memory 140. The processor 135 can be any custom made or commercially available processor, a central processing unit (CPU), an auxiliary processor among several processors associated with the DSL modem 140, a semiconductor based microprocessor (in the form of a microchip or chip set), a macroprocessor, or generally any device for executing software instructions.

The memory 140 can include any one or combination of volatile memory elements (e.g., random access memory (RAM, such as DRAM, SRAM, SDRAM, etc.)) and nonvolatile memory elements (e.g., ROM, hard drive, tape, CDROM, etc.). Moreover, the memory 140 may incorporate electronic, magnetic, optical, and/or other types of storage media. Note that the memory 140 can have a distributed architecture, where various components are situated remote from one another, but can be accessed by the processor 140.

The software in memory 140 may include one or more separate programs 155, 160, each of which comprises an ordered listing of executable instructions for implementing logical functions. In the example of FIG. 1B, the software in the memory 140 includes the TRAKS server application 160 and a suitable operating system (O/S) 155. The operating system 155 essentially controls the execution of other computer programs, such as the TRAKS server application 160, and provides scheduling, input-output control, memory management, and communication control and related services.

In one embodiment, among others, of the present disclosure, the TRAKS server application 160 is provided to users in a hyper-text markup language format. One skilled in the art should recognize that in alternative embodiments, among others, the TRAKS server application is a source program, executable program (object code), script, or any other entity comprising a set of instructions to be performed. When a source program, then the program needs to be translated via a compiler, assembler, interpreter, or the like, which may or may not be included within the memory 140, so as to operate properly in connection with the O/S 160. Furthermore, the TRAKS application 160 in some implementations, among others, is written as (a) an object oriented programming language, which has classes of data and methods, or (b) a procedure programming language, which has routines, subroutines, and/or functions, for example but not limited to, C, C++, Pascal, Basic, Fortran, Cobol, Perl, Java, PHP, and Ada.

The I/O devices 145 typically includes input devices, for example but not limited to, an RJ-45 or RJ-11 jack for sending/receiving a DSL signal to/from a CO 125 and an ethernet or universal serial bus (USB) jack for sending/receiving the DSL signal to/from the computer 100. Finally, the I/O devices 145 may further include devices that communicate both inputs and outputs, for instance but not limited to, a radio frequency (RF) or other transceiver, a telephonic interface, a bridge, a router, etc.

When the TRAKS server 120 is in operation, the processor 135 is configured to execute software stored within the memory 140, to communicate data to and from the memory 140, and to generally control operations of the DSL modem 105 pursuant to the software. The TRAKS application 160 and the O/S 155, in whole or in part, but typically the latter, are read by the processor 135, perhaps buffered within the processor 135, and then executed.

When the TRAKS application 160 is implemented in software, as is shown in FIG. 1B, it should be noted that the TRAKS application 160 can be stored on any computer readable medium for use by or in connection with any computer related system or method. In the context of this document, a computer readable medium is an electronic, magnetic, optical, or other physical device or means that can contain or store a computer program for use by or in connection with a computer related system or method. The TRAKS application 160 may be embodied in any computer-readable medium for use by or in connection with an instruction execution system, apparatus, or device, such as a computer-based system, processor-containing system, or other system that can fetch the instructions from the instruction execution system, apparatus, or device and execute the instructions. In the context of this document, a “computer-readable medium” can be any means that can store, communicate, or transport the program for use by or in connection with the instruction execution system, apparatus, or device. The computer readable medium can be, for example but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, device, or propagation medium. More specific examples (a nonexhaustive list) of the computer-readable medium would include the following: an electrical connection (electronic) having one or more wires, a portable computer diskette (magnetic), a random access memory (RAM) (electronic), a read-only memory (ROM) (electronic), an erasable programmable read-only memory (EPROM, EEPROM, or Flash memory) (electronic), an optical fiber (optical), and a portable compact disc read-only memory (CDROM) (optical).

A DRS server 122 may be configured similarly as to that of TRAKS server 120 such that a DRS application is implemented in software on the DRS server 122. In some embodiments, a DRS application 162 may even be hosted on the TRAKS server 120 that the DRS application and TRAKS application 160 are hosted on the same computer, as generally shown in FIG. 1B. Accordingly, TRAKS server 120 and DRS server 122 may share the same computing resources, in one embodiment, among others.

The TRAKS application 160 shown operates to assist in assigning work and collecting status information regarding projects and/or jobs that have been assigned to an RMC. In one embodiment, among others, drawings are being created/modified, and TRAKS helps to manage the assignment of the creation/modification work. Moreover, the TRAKS program 160 stored and executed on the TRAKS server 120 could assist in handling the considerable backlogs and congested plats present at most RBOC RMCs.

The TRAKS application 160, in one embodiment, among others is programmed to provide a number of dynamic, html-based web pages for remote users. Alternatively, the TRAKS application 160 is configured as a server application which can be remotely run and accessed by a manager/supervisor/draftsman. In this alternative embodiment, among others, the TRAKS server 120 would provide a stream of information (including formatting information) to the remote user's computer via the network 100.

Referring now to FIG. 2A, shown is a screen shot of an embodiment, among others, of a menu screen representation 200. The menu screen representation typically includes a number of link representations. A user who wishes to use one of the features of TRAKS typically selects the link representation by moving the mouse cursor representation (not shown) over the link representation and pressing a mouse button. The link representations in an embodiment, among others, of the present disclosure include: a “Western Fiber Conversion” link representation 202; a “Fiber Splice Menu” link representation 204; a “Job Status” link representation 206; a “View Your TRAKS Jobs” link representation 208; a “Validations List” link representation 210; a “Request a Splat” link representation 212; a “View Open Splats” link representation 214; an “Assign Splat Jobs” link representation 216; and, a “View Assigned Splat Jobs by ID” link representation 218. The “Western Fiber Conversion” link representation 202 when selected leads the user to a western fiber conversion menu page representation shown in FIG. 2B. The “Fiber Splice Menu” link representation 204 when selected leads the user to a fiber splice menu representation shown in FIG. 2C. The “Job Status” link representation 206 when selected enables the user to view the status of various jobs assigned to the user. The “Your TRAKS job log” link representation 208 when selected enables the user to view a log of his or her open jobs. The “Validations” link representation 210 when selected enables the user to view a validations screen representation that notifies the user whether to run validations when posting an authorization. The “Request a Splat” link representation 212, when selected, enables the user to request a split plat job be performed by the RMC personnel in accordance with FIG. 3. The “View Open Splats” link representation 214 enables a user to view open splat requests in accordance with FIGS. 7 and 8. The “Assign Splat Jobs” link representation 216, when selected, enables users to assign split plat jobs to a user identification code as shown in FIG. 5. The “View Assigned Splat Jobs by ID” link representation 218, when selected, enables users to view assigned split plat jobs by identification code as shown in FIGS. 9 and 10.

Referring now to FIG. 2B, shown is a screen shot of an embodiment, among others, of a west fiber conversion menu screen representation 216. A user would typically access this page by selecting the “West Fiber Conversion” link representation 202 of FIG. 2A. The user would then be present with a number of link representations 218-236. A “Start Printing Wirecenter” link representation 218 requests a print wirecenter screen representation, shown in FIG. 11, from the TRAKS application 160. An “Assign Wirecenter” link representation 220 requests an assign wirecenter screen representation as shown in FIG. 14. A “Mark Wirecenter Complete” link representation 222 requests a mark wirecenter complete screen representation as shown in FIG. 15. A “Wirecenter Printing Report” link representation 224 request a wirecenter printing report screen representation as shown in FIG. 12. A “View Available Wirecenters” link representation 226 requests a view available wirecenters screen representation as shown in FIG. 13. A “View Your Assigned Wirecenters” link representation 228 requests an assigned wirecenters screen representation as shown in FIG. 16. A “View All Assigned Wirecenters” link representation 230 requests a view assigned wirecenters screen representation as shown in FIG. 17. A “View Completed Wirecenters” link representation 232 requests a completed wirecenters screen representation as shown in FIG. 18. A “View Accepted Wirecenters” link representation 234 requests an accepted wirecenters screen representation as shown in FIG. 19. A “Fiber Conversion Summary” link representation 236 requests a project summary screen representation as shown in FIG. 20.

Referring now to FIG. 2C, shown is a screen shot of an embodiment, among others, of a fiber splice menu screen representation 240. A user would typically access this screen representation 240 by selecting the fiber splice link representation 204 of FIG. 2A. A “Select Open WC for Fiber Population” link representation 242 requests an open wirecenters screen representation as shown in FIG. 21. A “Close Fiber Job” link representation 244 requests a close fiber job screen representation as shown in FIG. 24. A “View Assigned WCs by ID” link representation 246 requests an assigned wirecenters by ID screen representation as shown in FIG. 25. A “View Completed WCs by ID” link representation 248 requests a completed wirecenters by ID screen representation as shown in FIG. 27. A “View All Assigned Fiber WCs” link representation 250 requests a view fiber wirecenters screen representation as shown in FIG. 29. A “View All Completed WCs” link representation 252 requests a completed jobs screen representation as shown in FIG. 30.

Occasionally a plat becomes too crowded such that a user such as an engineer or poster finds it difficult or inefficient to work with the plat. Because the RMC remains responsible for drawings, the RMC draftsmen are responsible for splitting the plats into manageable divisions, and performing drafting for the pre-posting and final post jobs. In those instances where a split plat is desired, the user requests a split plat (SPLAT) screen representation by selecting a split plat link representation in the TRAKS application 160, and submits a request to divide the single plat into multiple plats by using the split plat screen representation of FIG. 3. As shown with respect to FIG. 3, the split plat screen representation 300 typically prompts the user to enter location information about the plat. In one embodiment, among others, the location information typically includes the district name, the wirecenter name, and the name of the plat to be divided. As one skilled in the art should recognize, a wirecenter is typically associated with a central office. The wirecenter represents the area (homes, businesses, etc.) which the central office serves. These are typically provided by the user selecting a district from a district list representation 305 populated from a TRAKS database containing existing districts. Upon choosing a district a wirecenter list representation 310 populates, enabling the user to choose among the wirecenters available in the selected district. The user would then enter a plat name into the plat name field representation 315, and an identification into the “Your ID” field representation 320. Typically the identification includes a user ID issued to all employees. Upon entering an ID into the “Your ID” field representation 320, the user would typically select the “Submit Splat Request” button representation 325 to submit the split plat request. One skilled in the art should recognize that the plat assignment system, in some embodiments, among others, is configured such that only authorized users have access to enter split plat requests.

Referring now to FIG. 4, shown is a state selection screen representation 400 for the split plat workflow management. A supervisor typically uses this screen representation 400 to begin the assignment of a split plat job to a draftsman (poster). Typically the supervisor first selects the state in a split plat using a state selection representation 405. The user then selects the “View Unassigned SPLATs” button representation 410 to retrieve unassigned split plat jobs. The button representation 410 is typically selected by moving the mouse cursor representation over the button representation and pressing the left button of the mouse, however, the user could also use the keyboard, as is known in the art.

Referring now to FIG. 5, shown is a SPLAT job assignment screen representation 500. The supervisor would typically use the pulldown menu representation 505 to select any of the unassigned split plat jobs that exist in the state selected from the previous screen representation 400. Upon choosing an unassigned split plat, the supervisor typically enters a identification code associated with the draftsman (poster) to whom the supervisor desires to assign the split plat job. The identification code is typically entered into an “Assign To:” field representation 510. Upon completing the assignment screen field representations 505, 510, the supervisor selects the “Select” button representation 515 to record the assignment.

Referring now to FIG. 6, shown is a hardcopy front sheet screen representation 600 associated with the split plat assignment job. The supervisor typically receives this screen representation 600 after selecting the “Select” button representation 515 of the previous screen representation 500. The supervisor would typically print this screen representation 600 for the hardcopy of a file for the job request. A hardcopy file would then be created by a file clerk including the front sheet. Ultimately, the file is given to the draftsman responsible for completing the split plat job.

Referring to FIG. 7, shown is a “View Open SPLAT Jobs” screen representation 700. A supervisor would typically use the state selection representation 705 to select a state in which to view open split plat jobs. Upon selecting the “View Report” button representation 710, TRAKS would retrieve the open split plat jobs from memory, and format the open split plat jobs for viewing by the supervisor.

Referring now to FIG. 8, shown is an open split plat jobs screen representation 800. The open jobs screen representation 800 typically includes a number of column representations 805-845. Typically, in one embodiment, among others, these columns include: a “Priority” column representation 805; a “Job Number” column representation 810; a “Wirecenter” column representation 815; an “NPA” column representation 820; an “NPX” column representation 825; a “Plat” column representation 830; an “Assigned” date column representation 835; an “Assigned To” column representation 840; and an “Age” column representation 845. The “Priority” column representation 805 typically tracks the priority level associated with the open split plat jobs. The “Job Number” column representation 810 typically represents the job number associated with a particular split plat job. The “Wirecenter” column representation 815 typically discloses the wirecenter in the plat which needs to be divided is located. The “NPA” and “NPX” column representations 820, 825, respectively, typically represent the area code (NPA) and the exchange code (NPX), which, taken together, are a unique identifier for a wirecenter. The “Plat” column representation 830 typically includes the name of the plat which is to be split. The “Assigned” date column representation 835 typically tracks the date on which the split plat job was assigned, if it has been assigned. The “Assigned To” column representation 840 typically tracks the drafter (poster) to which the split plat job was assigned, if it has been assigned. In the embodiment shown, among others, the drafter's initials are used to identify the responsible drafter. However, in alternative embodiments, among others, the drafter's identification code is used. The “Age” column representation 845 typically keeps track of the number of days that the split plat job request has been pending. It should be recognized by one skilled in the art that the column could be made sortable if the supervisor desired to have the ability to organize the list according to any of the column representations.

Similarly, TRAKS also allows a manager/supervisor to view jobs assigned to a draftsman according to their unique user ID. Referring now to FIG. 9, shown is a view assigned split plat jobs by identification screen representation 900. A supervisor would typically enter a user's unique identification into a “Key In An ID” field representation 905. Then the supervisor would select the “View Report” button representation 910. Upon selecting the “View Report” button representation 910, a request would be sent to TRAKS to retrieve all split plat jobs assigned to the unique identification number entered.

Referring now to FIG. 10, shown is an “Assigned Splat Jobs by ID” screen representation 1000. This screen representation 1000 is typically reached after selecting the “View Report” button representation 910 of the previous screen representation 900. The “Assigned Splat Jobs by ID” screen representation 1000 is typically arranged into several column representations 1005-1040. The columns are typically arranged similarly to the columns of FIG. 8. However the column representations of FIG. 10, typically also include a “Completed” column representation 1040, and the screen representation 1000 includes a “Total” field representation 1045. The “Completed” column representation typically tracks the date upon which the draftsman has indicated that he or she has completed the job. The “Total” field representation 1045 is typically the number of jobs that have been assigned to the unique identification number provided previously.

In an alternative embodiment, among others, TRAKS is responsible for managing the assignment of drawings that are being redrawn. In an embodiment, among others, of TRAKS the drawings are being converted from an old drawings format called Predator to the EWO intelligent database format which supports drawings which include optical fiber. As such the project is referred to as fiber conversion. Predator is a drawing format that cannot support new tools available for the EWO drawings. Predator is available from Colortrac Ltd./ACTion Imaging Solutions of Littleton, Colo. The workflow for this project can be seen with regard to FIGS. 11-20. The RMC, in an embodiment, among others, begins by printing out all of the wirecenter drawings that are stored in the old format.

Referring now to FIG. 11, shown is a “Start Printing” screen representation 1100 which the employee uses to begin printing of a wirecenter. The employee typically chooses a wirecenter from a wirecenter pull-down menu representation 1105. The employee also enters a date as the begin print date in the date field representation 1110. The employee typically chooses the “Mark WC as Started” button representation 1115 upon completion of the previous items. The button representation 1115 does not typically start the printing, but marks the record as having been started. The printing is typically started by an employee responsible for printing the wirecenters. After the wirecenter has begun printing from the current Predator record, TRAKS marks the wirecenter as having begun being printed, such that other users will not reprint the wirecenter. After the wirecenter has been printed, the draftsman re-draws the plat using an EWO plat that has been created for each of the plats that comprise the wirecenter. Because the plats were previously in the Predator format, and an EWO version of the file does not exist, typically a regional land administration center (RLAC) is responsible for creating the EWO plats (files) for the draftsman.

Referring now to FIG. 12, shown is a “Wirecenter Printing Report” screen representation 1200. The “Wirecenter Printing Report” screen representation 1200 is typically operable to format data regarding the printing status of each of the wirecenters being converted and report the status to a manager. Typically the “Wirecenter Printing Report” screen representation is divided into a number of column representations 1205-1240. These column representations are typically self explanatory, and in one embodiment, among others, includes: a “State” column representation 1205; a “District” column representation 1210; a “WC” column representation 1215; a “CLLI_CODE” column representation 1220; an “Available” column representation 1225; a “Print Start” column representation 1230; a “QRTL” column representation 1235; and, a “Units” column representation 1240. The “State” column typically represents the state in which the wirecenter is located. The “District” column is a further breakdown of the location of the wirecenter. The “WC” column is a name associated with the wirecenter, and the “CLLI_CODE” column is a common language location identifier referring to the wirecenter. The “Available” column typically lists the dates that an RLAC makes land available. This is typically the date on which the RLAC has finished creating the file that corresponds to the piece of land that comprises the plat. The RLAC compiles information on plats from information provided by the outside plant engineers in the form of subdivision maps, builder plats, county maps, survey information, etc. The “Print Start” column typically represents the date that printing was started for the wirecenter. The “QRTL” typically represents the complexity of the conversion according to fiber units. The “Units” column typically represents the units of fiber that exist in the wirecenter according to financial data from corporate records. The manager is able to use the “Wirecenter Printing Report” to determine and report progress to his or her superiors. Moreover, each of the wirecenters are assigned a number of units (shown by the “Units” column representation 1240) which is operable to give the manager/supervisor a better understanding of the progress made on printing the wirecenters.

Referring now to FIG. 13, shown is a wirecenter availability screen representation 1300. The wirecenter availability screen representation 1300 typically shows the draftsmen, supervisor and/or manager which wirecenters are available for assignment. The availability of a wirecenter not only refers to the fact that the wirecenters have not been assigned to a draftsman, but also helps the manager keep track of which wirecenters the RLAC has made available to the draftsman. For example, there may be no wirecenters available for assignment on the wirecenter availability screen, however, the dearth of available wirecenters does not indicate that each of the wirecenters has been assigned for conversion. Rather, the lack of available wirecenters could indicate that the RLAC is not keeping up with the demand for available wirecenters, and allows the manager to know when the RLAC is not supplying the draftsman with work. The wirecenter availability screen representation 1300 in one embodiment, among others, typically includes: a “State” column representation 1305; a “District” column representation 1310; a “WC” column representation 1315; a “CLLI_CODE” column representation 1320; an “Available” column representation 1325; a “Print Start” column representation 1330; a “QRTL” column representation 1335; and, a “Units” column representation 1340. The “State” and “District” column representations 1305, 1310, respectively, typically represent the state and district in which the wirecenter is located. The “WC” column representation typically represents the wirecenter name. The “CLLI_CODE” column representation 1320 typically represents the CLLI code associate with the wirecenter. The “Available” column representation 1325 typically represents the date upon which the wirecenter was made available. The “Print Start” column representation 1330 typically represents the date upon which printing was started for the wirecenter. The “QRTL” column representation 1335 typically represents the quartile to which the wirecenter has been assigned. The “Units” column representation 1340 typically represents the number of fiber units that need to be converted within the wirecenter. The screen representation 1300 also typically includes a total field representation 1345 which represents a total of the number of available wirecenters reported.

Referring now to FIG. 14, shown is a wirecenter assignment screen representation 1400. The wirecenter assignment screen representation 1400 is operable to instruct TRAKS to assign a wirecenter to a draftsman. Typically the wirecenter assignment screen representation 1400 allows the user to assign the wirecenter to himself or herself, however, one skilled in the art should recognize that a supervisor/group leader could be placed in charge to assign wirecenters to draftsmen, not including himself or herself. The wirecenter assignment screen representation typically includes a “Choose a Wirecenter” pull-down menu representation 1405. The pull-down menu representation 1405 enables a user to choose a wirecenter to assign to himself or herself. Upon selecting a wirecenter, the user can select the “Assign WC to Yourself” button representation 1410. TRAKS will then receive the request and assign the wirecenter to the user logged in to the particular station from which the request was received.

Referring now to FIG. 15, shown is a wirecenter closing screen representation 1500. A draftsman would typically use this screen representation to close any wirecenters that he or she has assigned to himself or herself. The draftsman would typically close a wirecenter after having entered all of the existing drawings into the EWO system, making changes to the plats received from RLAC. After selecting the wirecenter using the wirecenter field representation 1505, and selecting the “Mark WC Complete” button representation 1510, TRAKS will change the status of the wirecenter to “Complete”.

Referring now to FIG. 16, shown is an assigned wirecenter screen representation 1600. The assigned wirecenter screen representation 1600 is operable to display the wirecenters that have been assigned to the user viewing the screen. Thus, if the user has only assigned himself or herself one wirecenter, only one wirecenter will appear on his or her assigned wirecenter screen representation 1600. The assigned wirecenter screen representation 1600 in one embodiment, among others typically includes: a “State” column representation 1605; a “District” column representation 1610; a “WC” column representation 1615; a “CLLI_CODE” column representation 1620; an “Available” column representation 1625; a “Print Start” column representation 1630; an “Assigned” column representation 1635; an “Assigned To” column representation 1640; and, a “Units” column representation 1645. The screen representation 1600 also typically includes a “Total” field representation 1650, which displays the number of records stored with regard to wirecenters assigned to a user identification.

Similarly, with reference to FIG. 17, shown is an assignment status screen representation 1700. The assignment status screen representation 1700 is typically used by a supervisor or manager to determine which wirecenters have been assigned, and which of the draftsmen have assigned himself or herself to a particular wirecenter. Moreover, the assignment status screen representation 1700 also denotes the state and district of the wirecenter, the common language location identifier (CLLI) code associate with the wirecenter, the date the wirecenter was made available, the date that printing was started on the wirecenter, the date the wirecenter was assigned and the units of fiber that are contained within the wirecenter. Each of these fields are typically displayed to the user under a number of column representations 1705-1745. Moreover, the screen representation 1700 also typically includes a “Total” field representation 1750 which displays the total number of wirecenters that have been assigned.

Referring now to FIG. 18, shown is a completed wirecenter screen representation 1800. A manager would typically use the completed wirecenter screen representation 1800 to view the wirecenters that have been completed to date. Each of the completed wirecenters, as closed by the draftsman using the close wirecenter screen representation 1500 of FIG. 15, would appear in the listing. The screen representation 1800 typically includes a number of column representations 1805-1845. These column representations 1805-1845 in one embodiment, among others, include: a “State” column representation 1805; a “District” column representation 1810; a “WC” column representation 1815; a “CLLI_CODE” column representation 1820; an “Assigned” column representation 1825; an “Assigned To” column representation 1830; a “Completed” column representation 1835; an “Hours” column representation 1840; and, a “Units” column representation 1845. The screen representation 1800 also typically includes a “Total” field representation 1850, which displays the number of records stored with regard to the completed wirecenters.

Referring now to FIG. 19, shown is an “Accepted Wirecenters” screen representation 1900. The accepted wirecenters are typically those wirecenters that have been completed, and then accepted by the manager. Typically, however, the manager has a specified period of time in which to accept the wirecenter as complete. At the end of this specified period of time, TRAKS will automatically accept a wirecenter. The automatic wirecenters can be marked as automatically accepted, and in one embodiment, among others, are color-coded to indicate automatic acceptance. The screen representation 1900 typically displays the data to the user in column form, which in one embodiment, among others, typically includes: a “QRTL” column representation 1905; a “State” column representation 1910; a “District” column representation 1915; a “WC” column representation 1920; a “CLLI_CODE” column representation 1925; an “Accepted” column representation 1930; and, an “Accepted By” column representation 1935. Each of column representations 1905-1925 have been previously described. The “Accepted” column representation 1930 typically represents the date on which the wirecenter was accepted by a supervisor (or automatically accepted). The “Accepted By” column representation 1935 typically represents the supervisor who accepted the wirecenter (“AUTO” indicates that the wirecenter was automatically accepted). The screen representation 1900 also typically includes a “Total” field representation 1940, which displays the number of records stored with regard to the accepted wirecenters.

Referring now to FIG. 20, shown is a “Drawing Conversion Summary” screen representation 2000. The “Drawing Conversion Summary” screen representation 200 is typically used by management to track the progress of the drawing conversions. These summaries can be used to project a completion date, a slippage of schedule, availability of wirecenters, etc. Summaries such as this are a particularly useful tool in determining productivity, bonuses, efficiency, etc., especially in an environment where much of the work is performed through contract employees that report to another entity.

Another job workflow that TRAKS is responsible for is a fiber conversion project which converts existing manhole and conduit representations in the EWO database to “Route Manhole” and “Route Conduit” features. Further, two cross-wirecenter splices are being added for each location in which a fiber cable crosses a wirecenter boundary into another wirecenter. These features typically create a logical connection in the EWO database, whereas previously the manhole and conduit representations were recognized as an “open” in the circuit. The cross-wirecenter splices similarly create a logical connection between wirecenter drawings.

Referring now to FIG. 21, shown is a representation of an opening screen representation 2100 to view available wirecenters for assignment (e.g., those which have not been updated or assigned). Typically, the user selects a state which he or she would like to view the available wirecenters from the state selection representation 2105. Upon selecting the state, the user typically selects the “View Unassigned Fiber WCs” button representation 2110. The “View Unassigned Fiber WCs” button representation typically requests a wirecenter assignment screen representation, as shown in FIG. 22, from TRAKS.

Referring now to FIG. 22, the user typically uses the wirecenter assignment screen representation 2200 select a wirecenter on which he or she would like to work. To do so, the user would typically use a pulldown menu representation 2205 to select the wirecenter. The user would then enter his or her identification code (or a supervisor would enter an identification code for a draftsman) into the ID field representation 2210, and select the “Select” button representation 2215 to assign the wirecenter to him or herself.

Referring now to FIG. 23, shown is an embodiment, among others, of a “Close Fiber Job” screen representation 2300. The draftsman typically uses this screen to close a job after the job has been completed. As explained above, completion typically involves changing each existing conduit and manhole to a “route conduit” and “route manhole”, respectively. Moreover, each location in which a fiber crosses a wirecenter, a cross-wirecenter splice is inserted. Upon completing a job the draftsman could choose a “Mark Wirecenter Complete” option from a main menu representation and receive the “Close Fiber Job” screen representation 2300 of FIG. 23. The draftsman would typically enter his or her user identification into an “ID” field representation 2305. The draftsman could then typically select the “List Your Fiber Jobs” button representation 2310 to request a list of jobs associated with his or her user identification.

Referring now to FIG. 24, shown is an embodiment, among others, of a “Select a Wirecenter to Complete” screen representation 2400. The “Select a Wirecenter to Complete” screen representation 2400 is typically reached after entering a user identification and selecting the button representation of FIG. 23. The “Select a Wirecenter to Complete” screen representation 2400 typically includes a pull-down menu representation 2405 including each of the wirecenters that are currently assigned to the user identification that was previously entered. Thus, the draftsman would typically scroll through the wirecenters that were assigned to his or her user identification and highlight a job that the draftsman desired to mark as complete. Upon highlighting a job, the draftsman can select the “Mark WC as Complete” button representation 2410. This button will send a request to TRAKS to mark the selected wirecenter as complete.

Referring now to FIG. 25, shown is an embodiment, among others, of a job reporting by user ID screen representation 2500. A manager or draftsman would typically use this screen to determine how many fiber splice jobs have been assigned to a user ID. In the screen representation 2500, a manager or draftsman typically enters a user identification (typically the user's own user ID if the user is a draftsman). Upon entering a user identification into the field representation 2505, the user would select the “View Report” button representation 2510 to view each of the jobs assigned to the user ID entered.

Referring now to FIG. 26, shown is an embodiment, among others, of a report screen representation 2600. A user would typically receive the screen representation 2600 after entering a user ID and selecting the “View Report” button representation 2510 of FIG. 25. The report screen representation typically includes a list of jobs assigned to the ID that was entered in the previous screen representation 2500. The list typically includes column representations 2605-2620 for each field related to a job. The column representations 2605-2620 in one embodiment, among others, include: the wirecenter; the NPA, which, as outlined above, describes an area code; the NPX, which, as outlined above describes an exchange code; and, an assignment date. The screen representation 2600 also typically includes a “Total” field representation 2625, which displays the number of records displayed with regard to the assigned jobs.

Referring now to FIG. 27, shown is a completed fiber splice job reporting by ID screen representation 2700. Typically, this screen representation 2700 enables a manager or draftsman to submit a user identification in order to view completed jobs assigned to that user identification. In particular, the user typically enters a user identification into the ID field representation 2705. Upon entering a user identification into the ID field representation 2705, the user typically selects a “View Report” button representation 2710 to view the completed jobs associated with the user identification entered. Upon selecting the “View Report” button representation, a request is sent to TRAKS to retrieve completed jobs associated with the user identification entered by the user.

Referring now to FIG. 28, shown is an embodiment, among others, of a “Jobs Completed by ID” screen representation 2800. The “Jobs Completed by ID” screen representation 2800 is typically sent to a user in response to a request submitted from screen representation 2700. The “Jobs Completed by ID” screen representation typically includes a number of column representations 2805-2820. The column representations typically describe the content of the column representation. In an embodiment, the column representations include, among others: a “Wirecenter” column representation 2805; an “NPA” column representation 2810; an “NPX” column representation 2815; and, a “Completed” column representation 2820. The screen representation 2800 further includes a “Total” field representation 2825 representing the total number of items that are listed in the report. The screen representation 2800 also typically includes a “Back to Fiber Splice Tracking Menu” link representation 2830, which, when selected requests the fiber splice tracking menu screen representation from TRAKS. The screen representation 2800 also typically includes a “Total” field representation 2835, which displays the number of records displayed with regard to the jobs completed by the entered user identification.

Referring now to FIG. 29, shown is an embodiment, among others, of a “Jobs Assigned to RMC East” screen representation 2900. A user typically requests this page from TRAKS by selecting to view all assigned wirecenters from the fiber splice tracking menu screen representation. The screen representation 2900 typically includes a chart representation having a number of column representations 2905-2925. In an embodiment, among others, the column representations include: a “Wirecenter” column representation 2905; an “NPA” column representation 2910; an “NPX” column representation 2915; an “Assigned” column representation 2920; and, a “Name” column representation. The “Wirecenter” column representation 2905 typically refers to the wirecenter associated with the entry. The “NPA” and “NPX” are described above. The “Assigned” column representation 2920 typically refers to the date on which the job was assigned. The “Name” column representation typically refers to the person to whom the job was assigned.

Referring now to FIG. 30, shown is an embodiment, among others, of a “Fiber Splice Reporting—Completed Jobs” screen representation 3000. The screen representation 3000 is typically used to determine the number of completed jobs by state. The user would typically choose a state from the pulldown menu representation 3005 using the mouse cursor. Upon selecting a state, a request would be sent to TRAKS to pull the completed jobs in the selected state from a database, and provide the completed jobs to the user.

Referring now to FIG. 31, shown is an embodiment, among others, of a completed jobs report screen representation 3100. The completed jobs report screen representation 3100 is typically sent to the user from TRAKS in response to the user requesting the completed jobs reporting page using the previous page representation 3000 by selecting a state. In particular, the completed jobs reporting screen representation 3100 includes a number of column representations 3105-3135. The column representations in an embodiment, among others, typically include: a “Wirecenter” column representation 3105; an “NPA” column representation 3110; an “NPX” column representation 3115; a “Completed” column representation 3120; a “Name” column representation 3125; an “Hours” column representation 3130; and, a “Prints” column representation 3135. The “Wirecenter,” “NPA,” “NPX,” “Completed,” and “Name” column representations 3105-3125 have been previously described. The “Hours” column representation 3130 typically relates the number of hours that have been logged on the job by the assignee. The “Prints” column representation 3135 typically relates the number of pages (“prints”) the job entails. As one skilled in the art should recognize, the “Hours” column representation typically allows for a quarter of an hour for each page. However, it should also be recognized that other values could be provided.

Referring now to FIG. 32, shown is a flowchart of an embodiment, among others, of a split plat workflow associated with the TRAKS application 160. The process begins at step 3200. Typically TRAKS first receives a submission from a user regarding a congested or illegible plat, as shown in step 3205. In an embodiment, among others, of the TRAKS application 160, TRAKS determines whether the submission was made by an engineer or other district personnel, as shown in step 3210. If the submission was not made by an engineer or other district personnel, TRAKS assigns a “Normal” priority to the split plat request in step 3215. A supervisor then uses TRAKS to assign a split plat job to a draftsman, and to print a cover sheet, as shown in step 3220. Alternatively, if the submission was made by an engineer or other district personnel, TRAKS assigns a “High” priority to the split plat request in step 3225. A supervisor or manager then assigns the job to a draftsman in step 3220.

In step 3230, the draftsman who is assigned to complete the split plat job performs the split plat, and posts the changes to the EWO system. In step 3235, after the drafter completes the split plat job, the drafter submits the split plat job with the TRAKS cover sheet to a “SPLAT basket.” The jobs in the splat basket are then typically checked by quality assurance personnel for errors in step 3240. TRAKS determines whether errors exist in step 3245, and if errors do exist, the split plat job is returned to the drafter for correction in step 3250. If there are no errors in the job, the split plat job is sent to a team member to create a job record and to assign print credit in TRAKS for the drafter in step 3265. In step 3270, the split plat job goes to a supervisor for final check. The split plat job is then filed in a “Splat Jobs” area in step 3275, and the process ends in step 3280.

Referring now to FIG. 33A, shown is a flowchart of an embodiment, among others, of the fiber conversion portion of the TRAKS application 160. The process begins in step 3300. In step 3302, the wirecenter land base is generated by RLAC/outside plant engineering design system (OPEDS). Then two processes typically occur in parallel. In the first process, the RLAC sends the wirecenter landbase to OPEDS for drawing (DGN) file creation in step 3304. OPEDS receives the landbase from RLAC, and generates the drawing files for EWO in step 3306. In step 3308 OPEDS makes the wirecenter available to the RMC in TRAKS. In step 3310, the RMC group lead distributes the wirecenter prints to a drafter. Returning to the second parallel process, in step 3312, OPEDS sends the name of the wirecenter to the RMC. In step 3314, the RMC receives the name of the wirecenter from OPEDS and marks the wirecenter for printing in TRAKS. In step 3316, TRAKS flags RMC fiber jobs for dual posting, since these jobs need fiber conversion in addition to conversion. TRAKS then stores a list of backlog fiber jobs in step 3318. One skilled in the art should recognize that the process continues at 3320 in FIG. 33B. Typically in parallel to step 3316, the RMC prints the land and researches the wirecenter for fiber facilities in step 3322. In step 3324, the researched prints are filed for future conversion. In step 3310 the first and second process converge and the RMC team lead distributes the prints to a drafter. The drafter then typically assigns the wirecenter prints received from the team lead to himself or herself using TRAKS in step 3326, and TRAKS drops the wirecenter from the available list. The drafter then typically posts fiber to wirecenter in EWO according to the RMC guidelines. The process then continues at 3330 in FIG. 33B. The drafter runs a validation on the jobs before posting in step 3332. If there are validation errors in step 3334, the drafter corrects the validation errors in step 3336, and runs another validation in step 3332. The drafter then posts the job as closed in step 3338, and turns in the wirecenter prints to a “Completed” basket. The drafter marks the wirecenter complete in TRAKS in step 3340.

Quality assurance then picks the completed job up from the “Completed” basket and checks wirecenter for adherence to the posting guidelines in step 3342. If there are posting errors in step 3344, the wirecenter is returned to the drafter to correct the errors in step 3346. In step 3348, the drafter corrects any posting errors and returns the job to the team lead. In step 3350, the wirecenter prints are filed in a “Completed” area. Similarly, if there are no posting errors found, the wirecenter prints are filed in the “Completed” area in step 3350.

In step 3352, the wirecenter is checked for database errors by an RMC team member. If there are database errors in step 3354, the wirecenter is returned to the draftsman for correction in step 3356. In step 3358, the draftsman corrects the database errors and returns the wirecenter to the team member for re-check. If there are no database errors, the RMC typically tries to accept or reject the wirecenter within ten days of the job being marked complete, as shown in step 3360. If ten days have not expired, in step 3362, the wirecenter is marked as accepted by an RMC team member. However, if ten days have expired, TRAKS automatically marks the wirecenter as accepted in step 3364. The RMC's role in the drawing conversion is then complete as shown in step 3366. Returning to marker 3320, if a conversion has been flagged for dual posting in step 3316, the RMC updates EWO with jobs from the TRAKS backlog in step 3370. The jobs are then shown as complete in TRAKS and archived in step 3372, and the process ends as shown in step 3374.

Referring now to FIG. 34, shown is a flowchart of an embodiment, among others, of a fiber splice/conversion workflow associated with the TRAKS application 160. The process begins at step 3400. Typically the drafter first assigns a wirecenter to himself or herself using the TRAKS application, as shown in step 3405. After assigning a wirecenter to himself or herself, the drafter typically performs a fiber data population in EWO in accordance with step 3410. After performing the fiber data population in EWO, the drafter closes the wirecenter in TRAKS, and TRAKS logs the date and hours required to complete the job and prints the TRAKS cover sheet in step 3415. The draftsman then turns in the TRAKS cover sheet to the “Completed” basket in step 3420. A job number is then created in TRAKS for the job by the project manager and print credit is assigned to the draftsman in step 3425. The process ends at step 3430.

A variety of jobs and their records may be tracked using an embodiment of TRAKS 120 and it is not intended for embodiments of TRAKS 120 to be limited to particular instances recited previously or hereinafter. As such, a variety of functions are capable of being performed by embodiments of TRAKS 120.

New revisions to software and equipment are an ongoing challenge and as new projects are brought online, the breadth and scope of TRAKS systems grow as does the need for contingency planning. Implementing a way to continue business in a coherent way during a possible disaster event is an imperative. A disaster is generally defined as the occurrence of any event that causes a significant disruption in TRAKS capabilities and functionality. An important role of the DRS 122 is to minimize the effect a disaster will have upon on-going TRAKS operations and functions.

Accordingly, another job workflow that TRAKS is responsible for involves a TRAKS Disaster Recovery System (DRS) that focuses on disaster recovery planning in the event of an extended TRAKS outage. Details such as equipment and software needed to function during an extended TRAKS outage are described in documentation facilitated and prepared by the DRS 122, in one embodiment. Further, instructions for using spreadsheets to tally data that could then be converted for importation into the restored TRAKS server(s) 120 is prepared by the DRS 122, in some embodiments.

Overall objectives of the TRAKS Disaster Recovery System (DRS) include to protect TRAKS resources and user-customers, to safeguard project data records for projects/units/teams that use TRAKS for various functions. Objectives also include ensuring the ability of TRAKS to function effectively in the event of a severe disruption to normal operating procedures for projects/units/teams. An important function of the DRS is to document TRAKS critical systems and functions for response, recovery, resumption, restoration, and return after severe disruption.

To help implement operations performed by DRS, a disaster recovery management team is assembled that is responsible for making sure certain tasks are performed that is pertinent to the DRS. The disaster recovery management team assigns or designates or makes sure that leaders or owners for business units or teams are identified for each function being performed by TRAKS for each business unit/team.

One embodiment of a DRS application 162 is a Web based application that is used to assess the impact a disaster would have on certain functions facilitated by TRAKS. In one embodiment, DRS application 162 provides a Web-based form that is contained in a module that interacts with TRAKS application 160 or may be part of TRAKS application 160. One embodiment, among others, of this Web-based interface or form 3500 is shown in FIG. 35. This “TRAKS Disruption Impact Analysis Form” is to be filled out by people (e.g., business unit owners or leaders) designated by the disaster recovery management team, as discussed above, that are likely to be affected in a negative way by a TRAKS outage.

An additional form, shown in FIG. 41, is called the “TRAKS Critical Function Processing Requirements Form.” This form helps defines a particular function, spells out the contact information for the business unit owner and a backup person responsible for the function, and a contingency plan (CP) for that function—outlining a way to temporarily perform the function during an extended TRAKS disruption.

Referring back to FIG. 35, a user, such as a designated business unit owner, selects the function that is being performed for his or her business unit/team from a dropdown box 3510 that is provided on the form 3500. Accordingly, the user designated for a particular work function proceeds to answer questions contained on the form. In the present example, five questions are listed on the form 3500.

For example, if a designated business unit owner for an “EWO CMR's Core” function should select this function from the list as shown in FIG. 36 in response to the first question 3550 that asked “Does your function fall within the drop-down list shown below?” and the corresponding prompt 3555 “If so, you will need to fill out this form.” Next, the owner should classify the criticality of this function in response to the second question 3560 that asks “How would you classify the criticality of this function?” Accordingly, a function is “critical” if it can remain disrupted for a brief period of time before an emergency contingency plan should be enacted and a function is “desirable” if it can remain disrupted for a long period of time before an emergency contingency plan needs to be enacted.

An example is provided on the form that explains that the “categories listed detail the length of time that a function can remain disrupted without an emergency contingency plan in the event of an extended TRAKS disruption.” The available options listed in a dropdown box 3520 for responding to the question are Critical; Essential; Necessary; or Desirable, as shown in FIG. 37.

This collected information assists outside program management (OSPRM) in reviewing all project functions supported by TRAKS and the effect a disaster may have upon them. Accordingly, the form 3500 also prompts the designated person to determine “To what extent is this function dependent upon the availability of TRAKS” as the third question 3570. Available choices are low, medium, high, and none, as shown in dropdown box 3530 of FIG. 38.

Another prompt asks “Should this function not be performed following a disaster, which one of the following choices would best describe the impact on your function” as the fourth question 3580. Available choices include Production, The BellSouth Project, Data Integrity, and Operating Efficiency, as shown in dropdown box 3540 of FIG. 39. For example, if nonperformance of a particular function would impact data integrity the most or operating efficiency, then that particular choice should be selected.

In one embodiment, DRS 122 further prompts the designated person or owner to provide further information if the particular function generates revenue or receives funding, as shown by question number 5 (4005) in FIG. 40. For example, the user is prompted to input revenue loss (e.g., in dollars) if this function were not performed following an extended TRAKS disruption based upon time accrued for 1 hour in the first input box 4010 provided. Further, the user is prompted to input “comments, such as additional costs based upon time accrued hourly, if this function were not performed” in the second input box 4020 provided. Similarly, prompts are provided for further inputs 4030, 4040 based upon time accrued daily; prompts are provided for further inputs 4050, 4060 based upon time accrued weekly; and prompts are provided for further inputs 4070, 4080 based upon time accrued monthly. This information may be considered by the disaster management recovery team in assessing the potential impact a disaster would have on respective business units if associated TRAKS functions are interrupted.

Next, in one embodiment, DRS 122 prompts for identification of the owner of the function and their backup to be provided in respective input boxes 4090 and 4095 along with contact information (e.g., phone and email information) that is to be provided in additional input boxes. An Add Impact Analysis Button 4097 may then be selected to have the information provided by the user accepted by the DRS 122 and considered by the disaster management team.

Accordingly, a second Web-based form is facilitated by one embodiment of GRS, as shown in FIG. 41, and may be launched by selecting a Contingency Planning Menu link 4099 provided in form 3500, as shown in FIG. 40 for one embodiment.

Data provided in filling out the first form 3500 is carried over to the second form 4100, in one embodiment. The second form 4100 is used to outline a contingency plan (CP) for a given function as part of the disaster recovery plan and is called the TRAKS Critical Function Processing Requirements Form in the present example. The contingency plan defined by the DRS is intended to outline a way to temporarily operate and perform a particular function during an extended TRAKS disruption. Once the contingency plan is defined using DRS 122, copy of the disaster recovery plan (containing the contingency plan) should be retained by the appropriate function owner in a safe place, readily accessible in the event of an emergency.

Updates to the disaster recovery plan (DRP) may be provided as needed or during scheduled updates of the DRP. The contingency plan (contained in the DRP) for a particular TRAKS function serves as a decisive guide for function owners and administrators for what to do in the event of an extended TRAKS disruption.

As shown in FIG. 41, one embodiment of DRS 122 prompts a user (e.g., designated owner for a particular function or function owner) to detail the steps performed for a particular TRAKS function under normal conditions and the order in which they are completed under TRAKS. This information is placed in the input box 4110 provided.

Further, the user is prompted to input and document a contingency plan strategy of how the necessary unit will perform these steps during a disaster recovery in the input box 4120 provided by DRS 122. For example, some of the steps may have to be manually performed instead of being automated under TRAKS.

The user is further prompted to develop a data restoration strategy for his or her function including priorities and a respective schedule. The strategy should include a data components necessary for the restoration of the function in resuming normal TRAKS operation related to maintaining project records for business units. For example, the strategy may involve maintaining a spreadsheet manually for necessary data components of pertinent project records. Accordingly, necessary data fields for the spreadsheet are inputted into input box 4120 so that a spreadsheet can be devised in a case of a disaster for recording the required information. GRS 122 also advises the user that “If using a spreadsheet is not possible, document the reason and a suitable alternative process” using the input box 4210, as shown in FIG. 42 (which depicts a continuation of the form from FIG. 41). After the user completes the requested information, the user can select the Submit CP Changes button 4220 to have the entered information accepted by the DRS 122 and considered by the disaster management team.

Information inputted by each function owner is compiled and recorded by DRS 122. A list of all the data fields received by the DRS 122 can be used to facilitate a data recovery process. By gathering this information from function owners using DRS 122 in advance of a disaster, this affords function owners the actual name of each field pertinent to their particular function if a disaster occurs. This knowledge makes restoration of data much more efficient and effective after a disaster occurs.

For example, FIG. 43 shows a contingency plan that is compiled from information gathered using DRS 122 for an “EWO CMR's Core” function. The information 4310 shown at the top portion of the plan is information that has been provided from a function owner using the “TRAKS Disruption Impact Analysis Form” of FIG. 35. The information 4320 provided at the bottom portion of the plan is information that has been provided from a function owner using the “TRAKS Critical Function Processing Requirements Form” of FIG. 41. This information may now be compiled as part of a disaster recovery plan for the respective TRAKS function.

Via information gathered using DRS 122, DRS can facilitate preparation of a disaster recovery plan and documentation which is intended as a systematic guide from disaster to recovery. Referring now to FIG. 44, one embodiment of a flowchart for providing a disaster recovery plan to the TRAKS system is described. In block 4410, information is compiled on the processes performed by TRAKS for each business unit that utilizes TRAKS. This information is then used to form (4420) a disaster recovery plan for each of these processes in case TRAKS is not available for an extended period of time. The basic approach, general assumptions, and sequence of events that need to be followed are clearly described (4430) in disaster recovery plan documentation facilitated by DRS.

In accordance with DRS 120, the disaster recovery plan (including contingency plan) is distributed (4440) to key administrators and all key function owners receive the plan as well as receiving periodic updates to their respective function. The general approach is to make the disaster recovery plan as threat-independent as possible. This means that it should be functional regardless of what type of disaster occurs.

While using the disaster recovery plan during a severe disruption, it may be in the best interest of the disaster recovery management team to modify previous directions. All alternative actions should be documented, and as soon as appropriate, the disaster recovery plan should be resumed and revisions made as appropriate (using DRS) after an incident that perhaps results in severe disruption to TRAKS user-customers.

During a disaster, normally available personnel may be rendered unavailable by a disaster or its aftermath, or may be otherwise unable to participate in the recovery. Therefore, procedures provided in the disaster recovery plan should be sufficiently detailed so someone other than the person primarily responsible for TRAKS can follow them. Accordingly, FIG. 45 provides a flow chart describing one embodiment of a process for constructing a disaster recovery procedure for a business unit. The procedure allows (4510) recovery of a critical subset (e.g., contingency plan) of a unit's critical function(s) during the recovery period so that the unit can continue critical operations adequately. A disaster may require user-customers to function with limited automated TRAKS support and some degradation of service, until full recovery is made. The recovery procedure enables (4520) user-customers to write special purpose programs so that functioning is able to effectively return to normal conditions. That is to say user-customers may need to first rebuild and/or re-enter data that was lost between the time of the last TRAKS backup and the time of the disaster/disruption. In the event computing resources and software such as a spreadsheet program are not available, the recovery procedures specify (4530) that data handling be entered into a spreadsheet manually during the period when TRAKS automated support is unavailable. When TRAKS becomes available again, the data is then entered (4540) into TRAKS from the manual entries.

The detection of an event which could result in a disaster affecting TRAKS user-customers and TRAKS systems and functions is designated as the responsibility of a development or support team for TRAKS, unit supervisors and project team leaders, or whoever first discovers and/or receives information about an emergency situation that may affect TRAKS normal operation. Referring now to FIG. 46, a flow chart describing a process for reporting a disaster situation is described.

As soon as an incident occurs that could result in a severe disruption to TRAKS, the on-site staff will contact (4610) the appropriate emergency authorities if needed to protect life and property and then take (4620) the necessary steps to minimize property damage and injury to people during the incident. Normally, TRAKS development team receives an initial notice through their respective alarm monitoring capabilities such as event logs and email automatic notifications if not on the scene. If the problem affects TRAKS and does not activate a normal alarm system or logging trigger, the development team is to be immediately notified (4630).

If the disaster is of sufficient magnitude, building contacts are notified (4640) where TRAKs servers and equipment are maintained. Once the appropriate authorities and building contacts have been notified, a TRAKS disaster recovery management team leader is notified (4650) so that the team can personally make an on-site evaluation of the disaster. The team leader contacts (4660) the individuals identified in the TRAKS DRP as primary and secondary contacts for function owners who may be adversely affected by an extended TRAKS disruption.

In the event of a major TRAKS disruption, possible damaged and needed responses are assessed. The TRAKS disaster recovery management team inspects the site of an incident involving TRAKS systems and applications and make an initial determination of the extent of the damage. Based on their assessment, all or part of the TRAKS DRP is initiated.

The team will decide if normal operations can be continued at the site and repairs can be started as soon as possible. For example, if minor damage is found, TRAKS processing may be restarted in a short time with no special recall of personnel, and anticipated downtime may be less than one day. In such a case, damage is likely to be to hardware, software, mechanical equipment, electrical equipment, or the facility housing the TRAKS equipment itself.

The team will also decide if normal operations can be continued or restarted with the assistance of only certain units or support teams. For example, if major damage is found, selected units or support teams will be called to direct restoration of normal operations at current site. Estimated downtime, in such a case, may be two to six days. Major damage is likely to involve TRAKS hardware or the facility housing TRAKS.

The disaster recovery management team will decide if limited TRAKS operations can be continued at the site and plans started to repair or replace unusable equipment. The team will also decide whether the nominal home or facility of TRAKS operations is destroyed to the extent that an alternate facility must be used. The team may further make determinations as to what extent that the TRAKS DRP must be initiated.

The team will decide on its plan of action and then notify (4670) senior management in the event of an extensive outage, as shown in the flow chart of FIG. 46. Supervisors and team leaders will then be contacted (4680) and informed of a contingency situation and they in turn will inform (4690) TRAKS user-customers.

Periodically, the DRP undergoes a review to confirm the incorporation of all changes since the prior period or quarter, in some implementations. This review could result in major revisions to the DRP. These revisions are distributed to all authorized personnel, who exchange their old DRP's for the newly revised DRP's. In addition, the disaster recovery DRP is maintained if any changes to the operating environment occur, such as: facility changes; equipment changes; major changes to existing applications; off site storage location changes; new software upgrades or installs; changes to backup procedures; changes to key personnel identified in the document, etc.

To illustrate some of the foregoing concepts, backup of computer data is one of the functions facilitated by TRAKS system. For example, as part of TRAKS normal processes, a backup procedure is routinely performed. Each TRAKS system runs a scheduled programming routine to compress TRAKS Web code into a zip file. Also each system runs a scheduled routine to dump all current MySQL (a popular database management program) table data into a text file complete with inserts to make putting data back a relatively easy task. Those files are also compressed.

For one embodiment, once a night these files are all copied to three separate computer repositories and to a Solaris Unix computer by Rsync (a popular program for synchronizing data between two network locations). Onsite, daily backups of critical module scripts for PHP code (an HTML embedded scripting language) necessary for the Web server to serve TRAKS functionality to the end users and SQL (a standardized query language for requesting information from a database) dumps are made from production servers to three repository computers. Also, daily backup of TRAKS Mechanized and Manual components is also kept on each server in another drive volume for maximum availability. Offsite, a TRAKS production server is synchronized with a failover server at another location. Code synchronizations occur once per day and database tables are synchronized in near real-time. Weekly tape is sent by company courier to be stored off-site.

TRAKS backup routine automatically keeps up with the most recent three days of backup files, deleting any that are older than three days and keeping a log of each deletion.

A TRAKS nightly status report is sent daily at 2:00 a.m. to members of TRAKS development team. It represents the end result of the copies that started at 7:00 p.m. the evening before. When the report is without errors, this means that the machines that currently serve TRAKS have each performed their scheduled database dump and code copy and were online and available to collect those files from, at the time the final TRAKS copy routine executes. This is the last step in a TRAKS disaster recovery backup routine. If the output revealed in this message shows no runtime errors and the directory listing at the end shows three recent copies of TRAKS current live systems, this then confirms that the heartbeat of TRAKS systems and backups are functional and freely available.

In the event, TRAKS has to be restored, the disaster recovery plan provides for a TRAKS restore operation. For example, MySQL, PHP, Rsync, etc. programs and files may have to be restored that are used in the backup routine.

Included in the DRP, instructions for downloading the necessary software for restoring TRAKS operation is provided. Also, the DRP provides example files are provided that show “typical” scripts and batch files.

In one embodiment, the respective DRP includes instructions for what software to download, where to install the software, how to install the software, and how to configure the software after it is installed. For example, to implement the restore process, and assuming a viable server is not available, a user may be advised by the DRP to have the strongest desktop available with a standard Windows 2000 Professional or Windows XP load and a connection to the intranet. The user may also be advised have a connection to the Internet to ensure the latest patched versions of software packages that will be needed, if possible.

In some embodiments, instructions are also provided for testing installed components. For example, instructions may be provided for writing scripts to test installed components and also contain descriptions of what results should appear like to determine if the installation is working properly. If a successful result is determined, SQL data and tables may be restored and backed up PHP files and directories may be uploaded to a TRAKS emergency Web server that backs up a main production server for TRAKS. Similar types of instructions are also provided for a DRP having directions for restoring TRAKS to a UNIX environment.

Referring now to FIG. 47, a flow chart describing one embodiment of a method for managing a recovery of data and data processes is shown. The flow chart begins at block 4710 where a user is prompted to provide information describing impact that an extended interruption of a project tracking system (e.g., TRAKS) would have on an work unit that uses the project tracking system to perform a particular workflow process. Further, the user is prompted (4720) to provide information describing steps to be taken for performing a particular workflow process if the project tracking system is inoperable for an extended period of time. Feedback received from the user is then stored (4730) in response to answering questions proposed by the prompt logic. Accordingly, information stored in a database for each work unit that utilizes the project tracking system to perform a particular workflow process is compiled. Other embodiments may request additional information to be provided by a user regarding work flow process(es) such that appropriate recovery plans can be prepared to handle such processes in case the project tracking system is not in operation for an extended period.

Process and function descriptions and blocks in flow charts can be understood as representing, in some embodiments, modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps in the process, and alternate implementations are included within the scope of the preferred embodiment of the present disclosure in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present disclosure. In addition, such functional elements can be implemented as logic embodied in hardware, software, firmware, or a combination thereof, among others. In some embodiments involving software implementations, such software comprises an ordered listing of executable instructions for implementing logical functions and can be embodied in any computer-readable medium for use by or in connection with an instruction execution system, apparatus, or device, such as a computer-based system, processor-containing system, or other system that can fetch the instructions from the instruction execution system, apparatus, or device and execute the instructions. In the context of this document, a computer-readable medium can be any means that can contain, store, communicate, propagate, or transport the software for use by or in connection with the instruction execution system, apparatus, or device.

Conditional language, such as, among others, “can,” “could,” “might,” or “may,” unless specifically stated otherwise, or otherwise understood within the context as used, is generally intended to convey that certain embodiments could include, but do not require, certain features, elements and/or steps. Thus, such conditional language is not generally intended to imply that features, elements and/or steps are in any way required for one or more embodiments or that one or more embodiments necessarily include logic for deciding, with or without user input or prompting, whether these features, elements and/or steps are included or are to be performed in any particular embodiment.

It should also be emphasized that the above-described embodiments of the present disclosure are merely possible examples of implementations set forth for a clear understanding of the principles of the disclosure. Many variations and modifications may be made to the above-described embodiment(s) of the disclosure without departing substantially from the principles of the disclosure. All such modifications and variations are intended to be included herein within the scope of this disclosure. 

1. A data recovery management system, comprising: prompt logic operable to prompt a user to provide information describing impact that an extended interruption of a project tracking system would have on an work unit that uses the project tracking system to perform a particular workflow process; a database coupled to the prompt logic, operable to store feedback received from the user in response to answering questions proposed by the prompt logic; and organizational logic operable to compile information stored in the database for each work unit that utilizes the project tracking system to perform a particular workflow process.
 2. The system of claim 1, further comprising: secondary prompt logic operable to prompt the user to provide information describing steps to be taken for performing a particular workflow process if the project tracking system is inoperable for an extended period of time.
 3. The system of claim 2, wherein the secondary prompt logic prompts for identification of data fields that coincide with types of information that the project tracking system tracks in normal operation of the particular workflow process.
 4. The system of claim 1, wherein the prompt logic prompts for a categorization of the particular function in terms of a length of time that the function can be disrupted without having to implement a contingency plan.
 5. The system of claim 1, wherein the prompt logic prompts for a categorization of the particular function in terms of a level of dependency of the particular function on availability of the project tracking system.
 6. The system of claim 1, wherein the prompt logic prompts for a characterization of revenue losses that would be experienced if the particular function were not performed during an extended disruption of the project tracking system.
 7. The system of claim 6, wherein the characterization of revenue is queried in terms of different periods of time.
 8. A method for managing recovery of data and data processes, comprising: prompting a user to provide information describing impact that an extended interruption of a project tracking system would have on an work unit that uses the project tracking system to perform a particular workflow process; storing feedback received from the user; and compiling information stored in a database for each work unit that utilizes the project tracking system to perform a particular workflow process.
 9. The method of claim 8, further comprising: prompting the user to provide information describing steps to be taken for performing a particular workflow process if the project tracking system is inoperable for an extended period of time.
 10. The method of claim 9, further comprising: prompting for identification of data fields that coincide with types of information that the project tracking system tracks in normal operation of the particular workflow process.
 11. The method of claim 8, further comprising: prompting for a categorization of the particular function in terms of a length of time that the function can be disrupted without having to implement a contingency plan.
 12. The method of claim 8, further comprising: prompting for a categorization of the particular function in terms of a level of dependency of the particular function on availability of the project tracking system.
 13. The method of claim 8, further comprising: prompting for a characterization of revenue losses that would be experienced if the particular function were not performed during an extended disruption of the project tracking system.
 14. The method of claim 8, wherein the characterization of revenue is queried in terms of different periods of time.
 15. A computer readable storage medium having a program for managing recovery of data and data processes, the program having instructions for performing: prompting a user to provide information describing impact that an extended interruption of a project tracking system would have on an work unit that uses the project tracking system to perform a particular workflow process; storing feedback received from the user; and compiling information stored in the database for each work unit that utilizes the project tracking system to perform a particular workflow process.
 16. The computer readable storage medium of claim 15, the program further performing: prompting the user to provide information describing steps to be taken for performing a particular workflow process if the project tracking system is inoperable for an extended period of time.
 17. The computer readable storage medium of claim 15, the program further performing: prompting for identification of data fields that coincide with types of information that the project tracking system tracks in normal operation of the particular workflow process.
 18. The computer readable storage medium of claim 15, the program further performing: prompting for a categorization of the particular function in terms of a length of time that the function can be disrupted without having to implement a contingency plan.
 19. The computer readable storage medium of claim 15, the program further performing: prompting for a categorization of the particular function in terms of a level of dependency of the particular function on availability of the project tracking system.
 20. The computer readable storage medium of claim 15, the program further performing: prompting for a characterization of revenue losses that would be experienced if the particular function were not performed during an extended disruption of the project tracking system. 